1. Introduction
Low economic growth is perhaps the Caribbean’s greatest Achilles’ heel. Studies that examined this issue have put forward various explanations and hypotheses to explain the region’s low growth performance, with most of them related to deep-rooted competitiveness problems and low levels of productivity, among other structural challenges (
Acevedo et al. 2013;
Alleyne et al. 2017a;
Fuentes et al. 2015). Some researchers and policymakers have argued that the Caribbean’s private sector should play a key role in promoting higher and more sustainable growth. However, the private sector in the Caribbean is currently characterised as being largely static and underperforming based on estimates of sales growth and total factor productivity (
Ruprah and Sierra 2016).
Research has shown that innovation is one of the most important sources of competitive advantage that can improve firm productivity and performance in a sustainable way (
Atalay et al. 2013;
Hall 2011;
Lööf and Heshmati 2006). However, firm-level innovation in the Caribbean is low relative to countries of comparable population size as evidenced by determinants such as expenditure on research and development, the number of patents registered per million persons and technology adoption by the government (
Ruprah and Sierra 2016).
While previous papers on innovation in the Caribbean have looked at other determinants of innovation such as firm characteristics (
Alleyne et al. 2017b) and in-firm training (
Mohan et al. 2017), there is a lack of information and/or analysis regarding the link between the human capital constraints that firms face and their decision to innovate. This is a particularly important policy issue as an “inadequately educated workforce” has been consistently identified by firms as the most important constraint to their performance (PROTEqIN Survey 2014; and World Bank Enterprise Survey 2010). The factors underlying this constraint have been attributed to worker emigration, low quality of education, inadequate training offered by local educational institutions, and skills shortages and mismatches (
Khadan 2017;
Mishra 2006).
Thus, this paper contributes to our understanding of this issue by examining the extent to which innovation decisions in the Caribbean are affected by educational mismatches and firms’ inability to find appropriately skilled workers.
1 In particular, the following four questions are empirically examined: (i) the extent to which firm-level innovation is affected by firms’ ability to find new skilled employees; (ii) the extent to which firm-level innovation is affected by educational mismatches at the managerial and professional levels of occupation; (iii) the extent to which firm-level innovation is affected by firms inability to find employees with core skills or job-related skills for various types of jobs; and (iv) the extent to which firm-level innovation is affected by in-firm training.
It has long been recognised that innovation activities in a country or firm require human capital with the ability to generate and apply knowledge and ideas. Indeed,
Kim (
2002, p. 92) noted that “more highly-educated individuals tend to adopt innovations earlier and implement and adapt them sooner than less-educated individuals.” Studies have found that innovation at the firm level is positively associated with workforce qualifications and expenditure on training (
Jones and Grimshaw 2012;
OECD 2011). Highly skilled and educated workers are thought to be more apt for generating ideas and adopting technologies to make improvements on existing products and processes. In a review of the literature on workforce skills and innovation,
Toner (
2011) found that cross-country differences in the quality and quantity of workforce skills are a major factor in explaining observed patterns of innovation.
Studies focusing on the skills mix required for successful innovation find that a wide variety of skills are important. In a study of the determinants of innovation capability in small firms,
Albaladejo and Romijn (
2000) also found that the skill mix of the workforce tends to be positively associated with innovation performance. Similarly,
Leiponen (
1996) also found that innovative firms have a more educated workforce than non-innovative firms (see also
Amara et al. 2008;
van Uden et al. 2014). The appropriate skillsets required for innovation at the firm level may also depend on the stage of innovation, the type of innovation and the type of industry. In a review of the literature, the
Organization for Economic Cooperation and Development (OECD) (
2011) found that a broad set of skills ranging from reading, writing, academic skills, technical skills, problem-solving, managerial and entrepreneurial skills and even “soft” skills are important to support innovation. Some researchers have emphasised the importance of practical skills and worker experience (
Gangl 2000;
Winkelmann 1996), while others have found more benefits from general education (
Dolton and Vignoles 2002;
Krueger and Kumar 2004).
The rest of this paper is organised as follows: section two briefly examines the level of innovation and the extent of educational mismatches in the Caribbean. Section three outlines the estimation strategy. Section four presents the results of econometric estimations related to the effects of skill and educational constraints on innovation decisions and section five concludes the paper with policy recommendations.
2. Education, Skills and Innovation in the Caribbean
The data used is this paper were obtained from the 2014 Productivity, Technology and Innovation (PROTEQIN) survey. The PROTEQIN survey, a representative sample of 1846 firms across 13 Caribbean countries, was the first of its kind to be carried out in the Caribbean, following the 2010 World Bank Enterprise Survey (WBES). The PROTEqIN survey includes more questions than the WBES on skills and education of employees than the WBES, which makes it possible to conduct an analysis of various aspects of the relationship between educational and skill levels of the firms’ workforce and innovation decisions. Moreover, the questions on innovation and educational attainment had a very high response rate across firms in all 13 countries.
Innovation at the firm level is generally low and varies across Caribbean countries. On average, roughly 19 percent of Caribbean firms reported having engaged in some form of innovation in the past three years, specifically, implementation of a new or significantly improved product or process, a new marketing method, or a new organizational method in business practices, workplace organization, or external relations. The range varies from the lowest, at 4.8 percent of firms in Dominica, to the highest at 53 percent of firms in Guyana. A higher proportion of firms reported their intention to engage in innovation in the next two years: an average of 35 percent of firms indicated that their intention to undertake technological innovation in the next two years and 39 percent expect to undertake non-technological innovation.
2 Not surprisingly, only 10.3 percent of firms in the Caribbean have an innovation department: the range varies from the lowest at 1.6 percent of firms in Dominica, to the highest, at 36.7 percent of firms in Guyana. In general, firms that have an innovation department are more likely to engage in innovation activities (
Table 1).
The PROTEqIN survey also makes it possible to determine the extent to which Caribbean firms are recruiting employees with the appropriate level of education. The PROTEqIN survey includes nine job types: managers; professionals, technicians and associate professionals; clerical support workers; service and sales workers; skilled agricultural, forestry, and fishery workers; craft and related trades workers; plant and machine operators and assemblers; and elementary occupations. Firms were asked to report on the minimum level of education required for each job type and the average level of education of their current workforce by job type. From this information, it is possible to determine the extent to which firms are recruiting employees with the adequate level of education across different job types.
Table 2 summarises the results and shows that some firms are unable to find employees with the minimum level of education. This is a more serious challenge for recruitment of managers and professionals.
Educational mismatches in selected Caribbean countries can be observed by combining information from labour force surveys with the PROTEqIN survey.
Figure 1 shows the results of an estimated distribution for labour demand using data derived from the 2014 PROTEqIN survey and an estimated distribution of labour supply by educational levels for Barbados, The Bahamas, Jamaica, and Trinidad and Tobago derived from each country’s Labour Force Surveys. The evidence suggests an undersupply of workers with university degrees and vocational training on the right side of the distribution and an oversupply of workers with lower levels of education (primary and secondary). It is therefore not surprising that an inadequately educated workforce is ranked as the most important constraint for firms’ performance (
Figure 2).
3. Methodology
This paper tackles four questions: (i) the extent to which firm-level innovation is affected by the firms’ ability to find new skilled employees; (ii) the extent to which firm-level innovation is affected by the educational mismatches at the managerial and professional levels of occupation; (iii) the extent to which firm-level innovation is affected by the firms inability to find employees with core skills or job-related skills; and (iv) the extent to which firm-level innovation is affected by in-firm training.
Three dependent variables reflecting innovation decisions are considered: (i) whether a firm introduced at least one type of innovation in the past three years = 1, otherwise = 0; (ii) whether a firm plans to pursue technological innovation in the next two years = 1, otherwise = 0; and (iii) whether a firm plans to pursue non-technological innovation in the next two years = 1, otherwise = 0, (see
Table 3). As each dependent variable is binary, a Probit model is used to estimate the marginal effects associated with factors affecting firms’ decision to innovate.
As this paper focuses on the extent to which education, skills and in-firm training of a firms’ workforce influences innovation, four questions from the PROTEqIN survey are used to construct a set of relevant explanatory variables, along with variables controlling for other standard determinants of innovation (see
Table A1 in the
Appendix). The first question—
Did your establishment have difficulty in finding new skilled employees?—was used to construct a dummy variable equal to 1 if the firm had difficulty finding new skilled employees and 0 otherwise.
The second question used asked firms to specify the minimum level of education required for nine job types, and the average level of education of the firms’ current workforce for the same nine job types. Educational levels and job types comprised five and nine categories, respectively (see
Table 2). Six variables are constructed based on whether there are reported differences between the minimum level of education required (M
R) for a specific job type and the average level of education required (A
R) for that type of job. The analysis focuses on managers and professionals. In the first instance, two dummy variables, one representing a
manager mismatch and another representing a
professional mismatch are defined as equal to 1 if M
R ≠ A
R, and 0 otherwise. In addition, four variables are defined to represent undereducated and overeducated managers and professionals as follows: if M
R < A
R then it is assumed that the firm employs human capital (managerial and or professional) that is undereducated for that position. If the M
R > A
R, then it is assumed that the firm employs human capital that is overeducated for that position. In this regard, two dummy variables are defined as equal to 1 if A
R < M
R and 0 otherwise, representing undereducated managers and undereducated professionals, respectively; another two dummy variables, each equal to 1 if A
R > M
R and 0 otherwise, represent overeducated managers and professionals, respectively (see
Table 4).
The third question which asks firms to report whether they had difficulty finding candidates with the appropriate skills (core or job-related) is used to construct another set of explanatory variables.
3 For each job type
j, a dummy variable is defined as
j = 1 if the firm reports that it is “difficult” to “almost impossible” to find candidates with the appropriate skills (core or job-related); and 0 if it is reported as “not difficult” to “slightly difficult”. This yields nine dummy variables, each equal to 1 if the firm had “difficulty” finding employees with core skills for the aforementioned nine job types and 0 otherwise; and another nine dummy variables, each equal to 1 if the firm had “difficulty” finding employees with job-related skills for the aforementioned nine job types (see
Table 4).
The fourth variable of interest examines whether in-firm training affects innovation. The question used here asked whether the firm ran formal training programs for its permanent, full-time employees in the last fiscal year, and if so what percentage of production (skilled and unskilled) and non-production workers received training. Two variables were constructed from this question: (i) the percentage of total production workers (skilled and unskilled) that received training and (ii) the percentage of total non-production workers that received training.
Table 5 provides summary statistics on the variables used in the regressions.
The regression to be estimated is specified as follows:
where
Innovation is a binary variable equal to 1 if the firm introduced at least one type of innovation in the last three years and 0 otherwise, or if the firm plans to undertake technological innovation in the next two years and 0 otherwise, or if the firm plans to undertake non-technological innovation in the next two years and 0 otherwise;
age is the number of years the firm has been in operation,
size is the number of employees in the firm at the end of the last fiscal year,
exporter is a dummy variable equal to 1 if the firm exports and 0 otherwise,
importer is a dummy variable equal to 1 if the firm imports and 0 otherwise, and
industry is a dummy variable equal to 1 if the firm is a manufacturer and 0 otherwise.
represents a vector of explanatory variables:
is a dummy variable equal to 1 if the firm has difficulty finding new skilled employees and 0 otherwise. is a vector of two dummy variables representing manager mismatch and professional mismatch, is a vector of four dummy variables representing undereducated managers, undereducated professionals, overeducated managers, and overeducated professionals. is a vector of nine dummy variables each equal to 1 if the firm had “difficulty” finding employees with core skills for nine job types; is a vector of nine dummy variables each equal to 1 if the firm had “difficulty” finding employees with job-related skills for nine job types. is a vector of two variables representing the share of production workers that received training and the share of non-production workers that received training. are the country fixed effects, are the coefficients to be estimated, and is a normally distributed error term. Six separate Probit regressions are estimated, one for each term on the right-hand side of Equation (2).
4. Results
The detailed results from the Probit regressions are presented in
Table A2,
Table A3,
Table A4,
Table A5 and
Table A6 in the
Appendix. The findings from the regressions show that the challenge that Caribbean firms face in recruiting skilled employees and educational mismatches in their workforce at the managerial and professional levels reduce the probability of innovation. Moreover, while the effects of in-firm training on innovation are positive and statistically significant, their magnitude is negligible. These findings generally hold for past innovation, and future innovation decisions related to technological and non-technological activities (
Table 6).
The other explanatory variables also show interesting results. The marginal effects of the exporters, firm age, firms size, and manufacturing industry dummies were all positive and statistically significant for past innovation. However, firm age was found to be statistically insignificant for both types of future innovations, and the variable representing exporting firms was found to be statistically insignificant for technological innovation only.
Firms that export are 8 percent more likely to engage in past innovation, and 0.4 percent and 7.6 percent more likely to pursue technological and non-technological innovation in the next two years, than non-exporters. Importers are 7.9 percent more likely to innovate, and 6.9 percent and 6.4 percent more likely to pursue technological and non-technological innovation in the next two years, than non-importers. This finding is consistent with other studies such as
Lin and Tang (
2013) who found that exporters tend to invest more in R&D compared to non-exporters. Theoretical models by
Atkeson and Burstein (
2010) and
Impullitti and Licandro (
2018) show that trade openness induces firms to increase innovation which is mostly explained by the increased competition firms face in international markets (see also
Melitz 2003).
Firm size is also found to be statistically significant, increasing innovation by 5.8 percent, as are plans to pursue future technological innovation and non-technological innovation by 5.3 percent and 4 percent, respectively. Similarly, although some papers have found that larger firms tend to invest more in research and development as they can amortize fixed costs over a broader base (
Palangkaraya et al. 2016), other studies have found that small firms are more efficient at innovation because they are more flexible and less bureaucratic than larger firms (
Becheikh et al. 2006;
Le Bas and Scellato 2014). Some studies that have examined the innovation and firm size relationship at the intensive margin draw negative or ambiguous conclusions (
Johansson and Lööf 2008). Finally, firms in the manufacturing sector are 16 percent more likely to innovate than firms in other sectors, and 12.1 percent and 6.7 percent more likely to pursue technological innovation and non-technological innovation, respectively, in the next two years.
The marginal effects associated with firms’ inability to find new skilled workers are equal to −0.048, −0.091, and −0.045 for past innovation, future technological innovation, and future non-technological innovation, respectively (i.e., lowering the probabilities of past and future innovations lower by 4.8 percent (past), 9.1 percent (future technological), and 4.5 percent (future non-technological)).
Table A3 and
Table A4 in the
Appendix present the results associated with a manager mismatch and a professional mismatch, that is, if the firms’ employees are either undereducated or overeducated for those two occupational categories. The marginal effects show that a manager mismatch lowers the probability of innovation by 4.7 percent and 6.6 percent for future technological innovation, while it is statistically insignificant for future non-technological innovation. Similarly, an educational mismatch of professionals lowers the probability of innovation by 4.6 percent but is statistically insignificant for both types of future innovation.
As educational mismatches can be classified as either overeducated or undereducated,
Table 6 provides the marginal effects associated with both occupational levels. The results show that overeducated and undereducated managers negatively affect past innovation and future technological innovation. The marginal effects for
overeducated managers show that it is relatively larger for future technological innovation, lowering by 13 percent and lowering past innovation by 7 percent. Undereducated managers also reduce the probability of past and future technological innovation by 4 percent and 5 percent, respectively. Moreover, having overeducated professionals increases the probability of future technological innovation by 8 percent, while having undereducated professionals lowers past innovation by 5 percent.
Table A5 in the
Appendix presents the results of regressions that examined the relationship between firms’ inability to find workers with appropriate core and job-related skills and innovation. In general, the marginal effects show that at least for three occupational categories, the probability of both past and future innovation is lowered, especially when firms are unable to find employees with the appropriate core skills. The marginal effects show that past innovation is lowered by 9 percent and 4 percent, respectively when firms have difficulty in finding managers with appropriate core and job-related skills, respectively. The effect is also statistically significant for future non-technological innovation, but insignificant for future technological innovation. However, future technological innovation is lowered by 18 percent and 9 percent when firms are unable to find professionals with the appropriate core skills and job-related skills, respectively. Difficulty in finding professionals with the appropriate core and job-related skills are also statistically significant for past innovation, and future non-technological innovation. Difficulty in finding labour with the appropriate core and job-related skills in other job categories such as skilled agricultural workers, craft workers, and plan and machine operators are found to affect the likelihood of innovation, particularly future innovation (see
Table A5 in the
Appendix).
With respect to training, the results in
Table A6 in the
Appendix show that training of both production and non-production workers is more likely to increase innovation.
Mohan et al. (
2017) in examining the determinants of in-firm training in the Caribbean found that it is positively related to firm characteristics such as firm size, being part of a larger firm, exporting, foreign ownership, and expenditure on R&D. These authors also found that training had a positive effect on innovation. The marginal effects reported in
Table A6 show that training of both production and non-production workers is positively associated with past and future innovation.
5. Conclusions
This paper sought to fill the gap on the extent to which human capital constraints affect past and future innovation decisions of Caribbean firms. Innovation in the Caribbean is relatively lower than in countries of comparable population size, and Caribbean firms have consistently ranked an “inadequately educated workforce” as their most serious obstacle to improving performance. Low innovation levels have been considered as an underlying cause of the region’s low economic growth and declining productivity levels. Thus, understanding the link between human capital constraints faced by firms and their innovation decisions is a critical issue for policymakers in the Caribbean. In that regard, this paper provides empirical evidence on the relationship between several dimensions of human capital constraints and past and future innovation decision of firms. The paper examined the determinants of firm innovation decisions, focusing on those related to human capital constraints, through several Probit models using firm-level data on 13 Caribbean countries.
The findings from this paper show that human capital constraints do have a statistically significant effect on firm innovation decisions in the Caribbean. Four aspects of human capital constraints were examined: (i) the difficulty of a firm finding new skilled workers; (ii) educational mismatches for managerial and professional job types; (iii) difficulty finding employees with core and job-related skills; and (iv) the importance of in-firm training. The paper shows that when firms’ have difficulty finding new skilled employees they are less likely to engage in any type of innovation, and this is also true for decisions about future technological and non-technological innovations. It was also found that educational mismatches for managerial and professional job types also lowers the likelihood of innovation. This effect is particularly important for future technological innovation when there are overeducated managers and professionals. Moreover, firms that face challenges to find employees with the required core and job-related skills at the managerial and professional levels are less likely to innovate, than those that do not. Finally, in-firm training is found to increase the probability of innovation, but its magnitude is low. In terms of the other traditional determinants of innovation, it was found that firm age, firm size, exporters, importers and manufacturing firms were statistically significant in increasing the probability of past innovation decision. However, for future technological innovation firm age and exporters were statistically insignificant, while for future non-technological innovation all the mentioned variables were statistically significant except for firm age.
The findings suggest that human capital constraints can potentially lower the likelihood of innovation among Caribbean firms. Such an outcome could have adverse macroeconomic implications through the lowering productivity growth. It is, therefore, important for policymakers to enact polices to address the underlying causes of educational and skill mismatches in the labour force and streamline education and training programs that are most relevant to the evolving demands of the labour market. Admittedly, the literature on the underlying factors causing human capital constraints in the Caribbean is sparse, but what exists suggests that the relatively deficient human capital stock is related to worker emigration, quality of education and training and perhaps the need for more relevant education and training programs. The latter may reflect gaps in education policies, information asymmetries between institutions that provide education and training and private sector demand for labour, and weak monitoring and evaluation mechanisms within the region’s education system. Further research in this area is needed along with better-quality data to make more conclusive policy statements. Additionally, given the low intensity of training reported by firms, there is significant potential to increase in-firm training and/or establish networks with both local and foreign institutions to design training programs that can enhance the quality and relevance of firms’ human capital stock within the Caribbean.
In terms of policy suggestions going forward, perhaps a starting point for policymakers is to evaluate the existing stock of programs designed to improve innovation, determine what is working and what is not, and make appropriate changes to the policy mix, as there are other factors apart from human capital constraints that influence innovation decisions.